DE3410662A1 - Method for generating at least one arbitrarily displaceable graticule on the screen of a screen device - Google Patents

Abstract

In this method, a first counter counts the number of lines scanned by the electron beam after each pulse of the frame clock. A second counter counts, after each pulse of the line clock, the number of dots imaged by the electron beam on each line. When the first counter has reached a predeterminable count n, then it outputs a signal which unblanks the nth line on the screen. This produces the horizontal line of the graticule. When the second counter has reached a predeterminable count m, it outputs a signal which causes unblanking of the mth dot on each line. This produces the vertical line of the graticule. An arbitrary number of graticules can be generated by connecting other pairs of counters in parallel. In the case of four counters which generate two graticules, the horizontal and vertical lines are shortened in such a way that a rectangle is produced on the screen.

Description

Method for generating at least one arbitrary

movable crosshairs on the screen of a display device The invention relates to a method for producing at least one which can be displaced as desired Crosshair on the screen of a video device that has a line clock having horizontal synchronization with which the interlacing of the electron beam be synchronized, which has an image clock for vertical synchronization, with which the beginning of the image is synchronized by moving the electron beam after returns to the starting point of the image after all lines have been traced, and that one pixel clock which divides each line into an equal number of pixels and with which the control of the electron beam is clocked.

The screen of a display device is divided into a multitude of lines divided - in television there are z. B. 624 lines - produced by an electron beam be driven off. When the electron beam hits all lines of the screen the entire process is repeated. This way, images will be on the Screen generated. So that the electron beam traverses the lines regularly, must he in horizontal and in verse synchronized in the tical direction will. With the clock for horizontal synchronization, the line clock, the Electron beam clocked from one line to the next while working with the Clock for vertical synchronization, the picture clock, returns to the beginning of the picture and scroll down the screen again line by line. Display devices for display of signs and graphics, in contrast to ordinary television, have one more thing further clock in addition to the line clock and the image clock. With this cycle, the pixel cycle, Also called dot clock, each line is broken down into a multitude of points.

As with normal television, the electron beam runs continuously along one line. However, its light-dark control is based on the pixel clock clocked so that the resolution of the pixels by the period of the pixel clock is determined. But you can also create a continuous line. Both Possibilities can e.g. with a shift register that is clocked by the pixel clock and its output signal controls the light keying of the electron beam will. If there is a zero-one sequence in the shift register, which corresponds to the pixel clock is pushed out, the electron beam is during the one clock period light, while the following are keyed dark. There is a line with a resolution determined by the period of the pixel clock. One continuous Line is created when there is a sequence of ones in the shift register that begins with the Pixel clock is pushed out. In contrast to television, display devices are used no gray values are displayed for characters and graphics, only light and dark Points that make up the characters or graphics. Display devices for characters and graphics are also with a light marker, the so-called cursor, fitted.

In the essay by Klein, R.-D .: The software for the mc graphics terminal, MC special issue No. 81 (1983), Franzis-Verlag Munich, pp. 58-65 explains how Text, graphics and light mark generated on the screen of a display device will.

As mentioned earlier, each line of the screen is in a multitude divided by dots so that the entire screen is divided into individual pixels is. A resolution of 512 x 512 pixels is common for many display devices. For each of these points a storage space is provided in an image memory, which requires a storage capacity of 26 Kbit with 512 x 512 pixels.

When entering text or graphics, combined text and and graphic display devices display the characters inputted point by point; H.

Bit by bit, written into an image memory. When characters are deleted, should be replaced by others or new characters inserted, the entire text or graphic point by point, i.e. bit by bit, into one written in the first frame buffer. Then in the first frame buffer the changes made point by point. Now the image becomes the image memory deleted on the screen and replaced by the corrected image of the first refresh memory replaced. You would at first Do without refresh memory and write the changes straight into the image memory, the image would be on the Screen flickers while enrolling. In addition, it is not possible to use the Read back image information or even the character codes from the image memory.

A second frame buffer is used to generate the light mark same size necessary. The light mark is in the second refresh memory like Text or graphic inscribed point by point. The memory locations of the second However, the refresh memory must never be occupied with text or graphics, because the light mark should be able to be moved anywhere on the screen without that this information is deleted. The light mark moves from one position to another, the points of the old position must first be deleted and then the points of the new position are described, which requires some computing time. The light mark appears on the screen when with a constant amount of joy switched back and forth between the image memory and the second frame repeat memory will. So the image of the image memory, i.e. text or graphics, are alternately and the image of the second frame buffer - the light mark - on the screen shown. Switching back and forth between the image memory and the second image repetition memory occurs at such a high frequency that the user cannot switch over perceives.

The light mark can take any shape. You can z. Belly have the shape of a crosshair, which means that the user can work on the screen the Presentation of graphics much easier. The crosshair can be moved and rotated as required.

As already mentioned, this requires the entire storage space of the second refresh memory required. Except for the image points of the crosshairs no further information is stored in the second frame buffer, so that a large amount of memory is required for one piece of information, namely the position of the crosshairs, is necessary, which only takes up a small fraction of the storage space. The remaining Storage spaces remain completely unused.

Because the old position when moving or rotating the crosshairs deleted and the new point by point, d. H. Bit by bit in the second frame buffer is written, a high computational effort is required, which is either too great Response times of the system leads or else to the response times in tolerable Keeping boundaries requires a very fast and therefore expensive computer.

The object of the invention is therefore to reduce the amount of memory required to generate a crosshair on the screen of a display device and at the same time the To reduce the computational effort when moving the crosshair.

The invention solves this problem in that the clock input (cl) a first counter (Z1) the line clock (ZT) is fed that the first counter (Z1) to a first predeterminable counter reading with each pulse of the image clock (BT) is set that the first counter (Z1) n clocks after the Set in the first predeterminable counter reading at one of its outputs (B, C) a signal abqibt, if the horizontal line of the crosshair should lie on the nth line, that the clock input (Cl) of a second counter (Z2) is supplied with the pixel clock (DT) is that the second counter (Z2) with each pulse of the line clock (ZT) on one second predeterminable counter reading is set that the second counter (Z2) in each case m cycles after setting the second predeterminable counter reading at one of its outputs (B, C) emits a signal when the vertical line of the crosshair passes through the m-th Pixel of each line should go that the signal that the first counter (Z1) at one of its outputs (B, C), causes the light keying of the nth line and that the signal that the second counter (Z2) emits at one of its outputs (, C), causes the light keying of the m-th pixel on each line.

1 shows a circuit arrangement for carrying out the The method of claim 2, shown in FIG. 2 shows an embodiment of the in Fi9. 1 shown Circuit arrangement and FIG. 3 shows an embodiment of the one shown in FIG Schaltunosanordnunc.

Look at the in the Fic: 1 shown scheme is the According to claim 1, the method according to the invention is explained.

In Fig. 1, the load Finoanq L of a counter Z1 with the image clock output BT of the screen control device S connected, in which in addition to the image clock BT and the Line clock ZT, the pixel clock DT and generates the video signal VS will. The line clock output ZT of the screen control device S is with the clock input Cl of the counter Z1 and the load input L of a counter Z2, whose clock input Cl is connected to the pixel clock output DT of the screen control device S. The borrow output B of the counter Z1 is connected to the first input and the borrow output B of the counter Z2 is connected to the second input of an OR gate 01, whose Output is connected to the first input of an OR gate 02. The exit of the OR gate 02 is connected to the video amplifier W, while its second Input is connected to the video signal output VS of the screen control device S. The data inputs of the counter Z1 are via a data line D1 with a coordinate memory K1 connected. A coordinate memory K2, which via a data line D2 with the Data inputs of the counter Z2 is connected, is also together with the coordinate memory K1 is connected to the computer R of the display device via a common data line D3.

If a crosshair is to be created, its horizontal line should lie on the nth line and its vertical line through the mth points all lines should go, the coordinate n is in the coordinate memory K1 and the coordinate m entered into the coordinate memory K2. Using the keyboard and the computer of the screen device, the user can change coordinates at any time for the horizontal and vertical lines of the crosshairs. With everybody Pulse of the picture clock BT, the counter Z1 is set to the counter reading n. because with each pulse of the line clock ZT the count of the counter Z1 is decreased by one, the count has dropped to 0 after n clocks. Of the Counter Z1 therefore emits a signal at its borrow output B via the OR gate 01 and 02 is fed to the video amplifier W and thus the light keying of the nth Line on the screen, because the electron beam travels at the nth cycle yes just the nth line on the screen. When the electron beam is the whole Screen has scanned, it returns with the now following pulse of the picture clock BT back to the picture starting point. At the same time the counter Z1 with this pulse set again to counter reading n, unless a new coordinate has been entered in the meantime entered into coordinate memory K1 for the horizontal line of the crosshairs has been.

If a new coordinate has been entered, the next run of the electron beam, not the nth, but the newly entered line is lightly keyed.

The vertical line of the crosshair is created in a similar way. When the vertical line of the crosshairs go through the mth points of all the lines should, the coordinate m is stored in the coordinate memory using the keyboard and the computer K2 entered. With every pulse of the line cycle ZT - i.e. with every line jump - the counter Z2 is set to the counter reading m. Because with every pulse of the pixel clock DT the count of the counter Z2 is decreased by one, the count is after m cycles dropped to 0. Because m cycles after each line jump the electron beam just hits the m-th point of the line and at the same time the counter reading of the Counter Z2 to 0 has decreased, the counter Z2 enters each time Siqnal at its borrow output B when the electron beam hits the m-th point every line hits. Because this signal is just like the signal at the borrow output B of the counter Z1 is fed to the video amplifier W via the OR gates 01 and 02 is, the m-th point on each line is lighted.

This creates the one formed by the m-th points of each line vertical line of the crosshair.

To move it, you can only see its new coordinate. then is no longer the m-th point, but the point with the new in the coordinate memory K2 entered coordinate lightly keyed on each line.

Instead of the borrow output B, the carry output C can be the Counters Z1 and Z2 be connected to the OR gate 01, as addressed in claim 4 is. In this case the counter Z1 does not count with each pulse of the line clock ZT backwards, but forwards. Likewise, the count of the counter 22 with each The pulse of the pixel clock DT increased by one. When the horizontal line of the crosshair is to go through the nth line, the counter Z1 with each pulse of the picture clock BT brought to the counter reading, which results from the complement increased by one n results. Because the counter Z1 has reached its maximum level after n clocks, there are it sends an overflow signal to its carry output C, which like the signal on Borrow output B in the circuit arrangement described above causes the n-th line is keyed lightly. When the vertical line of the Crosshair should go through the m-th points of all lines, the counter Z2 with each pulse of the line clock ZT brought to the counter reading, which increased from the by one Complement to m gives. Because the counter Z2 reaches its highest level after m clocks, if it sends an overflow signal to its carry output C, through which on every line the m-th point is lightly keyed. The vertical line of the crosshairs will be like already mentioned, formed from the m-th points of all lines.

A comparison between a conventional screen device that alone the entire storage capacity of an image repeater to generate a crosshair required, with a screen device that works according to the method according to the invention, clearly shows the saving in storage space achieved with the invention. A high-resolution display device with a resolution of e.g. 1024 x 1448 pixels requires an image memory with a storage capacity of 181 KByte. Instead of this refresh memory with a storage capacity of 1024 x 1448 bit = 181 KByte is sufficient for a screen device that uses the method according to the invention works and is equipped with dual counters, a memory with a storage capacity of 10 bits + 11 bits = 21 bits. The received numbers n and m are in the Coordinate storage is dual-coded and in dual form via the data lines D1 and D2 are supplied to the counters Z1 and Z2, which are designed as dual counters. The invention however, it is not restricted to the use of dual counters. Others can too Counters are used when the numbers n and m are coded accordingly.

But also the computational effort when moving the crosshair is much less, because instead of the new position of the crosshair point by point, d. H. Bit by bit to be written into the frame buffer only the new coordinates of the crosshairs are written into the coordinate memory. As a result, and through the use of counters, the movements of the crosshairs can be carried out very quickly without the need for extremely fast computers, which, moreover, while controlling the movements of the crosshairs on the screen, cannot take on any further tasks. However, according to the invention Move the crosshair lines only parallel to the edges of the screen; Rotation of the crosshair, as allowed by a screen device, in which the crosshair is generated by means of a frame buffer, are not possible. In in practice, however, rotations are rarely required.

An advantage of the invention is that any number of circuit arrangements can be switched together. Therefore, several crosshairs can be used at the same time generated and position changes on the screen without an extremely fast computer run very quickly.

In Fig. 2, a circuit arrangement is now shown with the simultaneous two crosshairs can be generated and moved. It differs from that Circuit arrangement for generating a crosshair in that two further counters Z3 and Z4 as well as two further coordinate memories K3 and K4 provided are. The coordinate memory K3 is connected to the data inputs via a data line D4 of the counter Z3 connected, while the data inputs of the counter Z4 via a data line D5 are connected to the coordinate memory K4.

Furthermore, the two coordinate memories K3 and K4 are via the data line D3 connected to the computer R of the display device. The control inputs of the counter Z3 are connected in parallel to the control inputs of the counter Z1; so are they Control inputs of the counter Z4 connected in parallel to the control inputs of the counter Z2. Depending on whether the counters Z3 and Z4 count backwards or forwards, the borrowing or the carry output of the counter Z3 with the third input of the OR gate 01 and the borrow or carry output of the counter Z4 to the fourth input of the OR gate 01 connected.

In the same way already explained, as with the counter Z1 the horizontal and how the vertical line of the first crosshair is generated with the counter Z2, the horizontal line with the counter Z3 and the vertical line with the counter Z4 of the second crosshair.

Although the memory usage is in contrast to that of a conventional Screen device doubled by the two other coordinate memories K3 and K4 has, it is still far below the storage capacity of an image refresh memory, because in the prior art, a storage capacity is used in the numerical example given of 1.5 x 106 bits is required, while the invention has a storage capacity of only 42 bits get by. On the other hand, the computational effort doubles at the Moving the two crosshairs on the screen both in the case of the one shown in Fig. 2 as well as in a conventional video display device. Because of the extremely high computational effort in conventional display devices, its doubling is particularly disadvantageous, while the computational effort at the circuit arrangement from FIG. 2 is still wide despite its doubling is less than the effort it takes to turn a single crosshair into one Rewrite the refresh memory.

If the two crosshairs do not coincide on the screen are positioned, form the four intersections of the two horizontal and the two vertical lines form the corners of a rectangle.

The length and width of the rectangle formed in this way can be as well as change its position on the screen at will. By suitable switching measures it is possible to hide all straight lines except for the sides of the rectangle, with the z. B. a certain area of a graphic can be outlined. On this Common graphics processing operations such as deleting, inverting, Blackening, swapping, etc. can be applied.

In Fig. 3, a Schaltunasanordnung is shown in which the disruptive lines extending beyond the corners of the rectangle can be hidden. It differs from the circuit arrangement shown in FIG is, in that a digital circuit arrangement as described below is, between the borrow or carry outputs of the counters Z1, Z2, Z3 and Z4 and the four inputs of the OR gate O1 is inserted.

The borrow output B of the counter Z1, which shows the position of the horizontal Line of the first crosshair is with the first input of a NOR gate N01 and the first input of a NAND gate NA1, the second input of which with the first input of a NOR gate N02 and with the borrow output B of the counter Z3 is connected, which defines the position of the horizontal line of the second crosshair. The borrow output B of the counter 22, which is the position of the vertical line of the first Crosshair is determined with the first input of a NOR gate N04 and the first input of a NAND gate NA2 connected, the second input with the first input of a NOR gate N03 and to the borrow output B of the counter Z4 which defines the position of the vertical line of the second crosshair. The output of the NAND gate NA1 is connected to the clock input of a flip-flop FF1, its pkeset input with the image clock output BT of the screen control device S connected is. The output of the NAND gate NA2 is with the Takteinqana of a flip-flop FF2 connected, its PReset-Finaang with the line clock output ZT of the screen control unit S is connected. The K-Einqänqe both flip-flops FF1 and FF2 are on "Low", while their inputs are at nHigh ". The Q output of the flip-flop FF1 is with connected to the first input of an AND gate V1. With the first entrance one AND gate U2 is connected to the Q output of flip-flop FF2. The two together connected second inputs of the AND gates U1 and U2 are at the computer R of the display unit connected. At the output of the AND gate U1 are the second input of NOR gate N03 and the second input of NOR gate N04 connected, while the second input of the NOR gate N01 and the second input of the NOR gate N02 are connected to the output of the second AND gate U2. The output of the NOR gate N01 is with the first, the output of the NOR gate N02 is with the second, the The output of the NOR gate N03 is connected to the third and the output of the NOR gate N04 is connected to the fourth input of the OR gate 01. The rest of the connections are the same as in the circuit arrangement from FIG. 2.

To the mode of operation of the circuit arrangement shown in FIG To be able to explain more easily, it is assumed first of all from the case that the lines the two crosshairs across the entire screen. Then the Consider the case that the two crosshairs are only a rectangle without the up to Form running lines around the edge of the screen.

When the lines of the crosshairs are all over the screen should, the second inputs of the AND gates U1 and U2 are set to "Low", see above that the second input of each NOR gate N01, N02, N03 and N04 is set to "Low" lies. The counters Z1, Z2, Z3 and Z4 are counters that are on their borrow outputs B go from "high" to "low" when they reach the counter reading Reach zero.

As long as no counter reaches zero Has, all inputs of the NOR gates N01, N02, N03 and N04 are on "High", so that the Outputs of these NOR gates are at Loww. Because the video amplifier W is therefore not a Receives a signal from OR gate 01, no crosshairs appear on the screen. Only when the count of one of the four counters has dropped to zero will it be Line whose position on the screen is determined by this counter, lightly keyed. if z. B. the counter Z1, which shows the position of the horizontal line of the first crosshair determines the counter reading has reached zero, the signal goes to its borrow output B from the high "state" to the 11Low state.

Because both inputs of the NOR gate N01 are now at wLoww, there are it emits a signal at its output, which, via the OR gates 01 and 02 to the video amplifier W reaching causes the line on which the horizontal line of the first The crosshair is to be located, is keyed lightly. Arise in the same way all lines, both horizontal and vertical, of the two crosshairs.

Let us now consider the case that there is only one rectangle on the Screen is displayed and beyond its corners to the edge of the screen extending lines are hidden.

For this purpose, the second inputs of the AND gates U1 and U2 set to High'1. For a better understanding of the following explanations it is assumed that that the horizontal line of the first crosshair on the nth line and the horizontal Line of the second crosshair lies on the (n + k) -th line. The vertical line of the first crosshair should go through the m-th points, the vertical The line of the second crosshair, on the other hand, goes through the (m + l) -th points of the lines. Like the top horizontal side of the rectangle on the nth row, however delimited by the vertical lines of the rectangle, is created in the following explained.

The flip-flop FF2 is reset with every pulse of the line clock ZT, so that its Q output, which is connected to the first input of the AND gate U2, is on "high". As long as the counters Z2 and Z4, which indicate the position of the vertical lines set, have not reached the counter reading zero, the signals go to their Borrow outputs B do not change from the "High" state to the "Low" state. That's why the flip-flop FF2 does not receive a clock pulse from the NAND gate NA2 and therefore remains in the reset state. When the count of the counter Z1 has dropped to zero is, the electron beam starts to move along the nth line. Simultaneously the first input of the NOR gate N01 is at "Low"; but because the flip-flop FF2 remains reset until it receives a clock pulse, the second lie Input of the NOR gate N01 and the NOR gate N02 continue to "Eligh" because the two inputs of the AND gate U2 are on "high". Because the NOR gates N01 and NO2 are blocked, no signal can be used to light the key via the OR gates 01 and 02 to get to the video amplifier W. Only when the electron beam hits the mth Point of the nth line is steered, the counter Z2 also has the counter reading zero achieved.

The signal at its borrow output B changes from "high" to "low" and thereby causes the flip-flop FF2 to send a clock pulse via the NAND gate ter NA2 receives. It therefore tilts, so that now the first input of the AND gate U2, which is connected to the Q output of the flip-flop FF2 is at "Low" while its second input is still on "High". Because the exit of the AND gate V2 is now also at "Low", both inputs of the NOR gate N01 are available tLow ", so that the NOR gate N01 sends a pulse to the OR gate 01. This Impulse causes the m-th point and all subsequent points on the n-th line be keyed brightly until the flip-flop FF2 flips back again. But that's just it then the case when the count of the counter Z4, which indicates the position of the vertical Line of the second crosshair has dropped to zero.

At the same time the electron beam is at the (m + l) -th point on the nth line angelanat.

By tilting back the flip-flop FF2 caused by a Clock pulse at the output of the NAND gate NA2 when the count of the counter Z4 is zero, the output of the AND gate U2 goes back to "hin", whereby the NOR gate N01 is blocked. There is therefore no more signal to the video amplifier W. On this On the nth line, only the points m to m + 1 are lightly scanned; it arises the top of the rectangle. Its lower side is created in the same way, when the count of the counter Z3 has dropped to zero.

Then the video amplifier W receives a signal from the NOR gate N02 as long as how the flip-flop FF2 stays tilted. When it falls back again, caused by the count zero of the counter Z4, the NOR gate N02 is blocked again, see above that also on the (n + k) -th line only the points m to (m + l) are lightly keyed.

As will be shown further, the right and left verticals arise Side of the rectangle in a similar fashion.

The flip-flop FF1 is reset with every pulse of the picture clock BT, so that its Q output, which is connected to the first input of the AND gate U1, is on "high". As long as the counters Z1 and Z3, which is the position of the horizontal Define lines, have not reached the counter reading zero, the signals go on their borrow outputs B do not change from the "High" state to the "Low" state. That's why the flip-flop FF1 does not receive a clock pulse from the NAND gate NA1 and therefore remains in the reset state. Every time the count of the counter Z2 is zero has decreased, the electron beam is directed to the m-th point of each line. The signal at the borrow output B of the counter Z2 then goes from the "High" state to the "Low" state above. However, as long as the flip-flop FF1 is not tilted, it is the first input of the NOR gate N04 to "Low", but the second to "High", because the first and the second input of the AND gate U1 are also on "Hiqh". Only when the electron beam is directed to the nth row does the flip-flop tilt FF1, because it receives a clock pulse from the NAND gate NA1, because the counter reading of the counter Z1 has dropped to zero at this point in time. Because by tipping of the flip-flop FF1, the output of the AND gate U1 and thus also the first input of the NOR gate N04 are at "Low", the NOR gate N04 outputs a signal via the OR gates 01 and 02 to the video amplifier W from when the counter reading of the counter Z2 has dropped to zero, and the NOR gate ter N03 gives a signal to the video amplifier W when the count of the counter Z4 has dropped to zero is. Therefore, on the nth line and on each subsequent line, the The m-th and the (m + l) -th point are lightly keyed until the flip-flop FF1 tilts back again and blocks the NOR gates N03 and N04 via the AND gate U1. The flip-flop FF1 tilts back exactly when the count of the counter Z3, which is the position of the horizontal Line of the second crosshair determined to have dropped to zero. Because at this point the electron beam traverses the (n + k) -th line are only on the lines between of the n-th and (n + k) -th lines, the m-th and (m + l) -th points are lightly keyed. This creates the vertical sides of the rectangle.

It is also possible instead of the four NOR gates N01, N02, N03 and N04 to use four OR gates if the OR gate 01 is through a NAND gate is replaced.

The position and size of the rectangle on the screen can be entered by typing new coordinates in the coordinate memories K1, K2, K3 and K4 changed as required will.

A major advantage of all the circuit arrangements described lies in the fact that they can be easily integrated into one module.

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Claims (10)

Claims (1.) Any method for generating at least one movable crosshair on the screen of a display device that has a Has line clock (ZT) for horizontal synchronization, with which the line jumps of the electron beam are synchronized, which has a Pildtakt (BT) to the vertical Has synchronization with which the beginning of the picture is synchronized by the Electron beam returns to the image starting point after all lines have been traveled, and which has a pixel clock (DT) that divides each line in an equal number divided by pixels and clocked with de the control of the electron beam is, characterized in that the clock input (Cl) of a first counter (Z1) the line clock (ZT) is fed that the first counter (1) with each pulse of the Picture clock (RT) is set to a first predeterminable counter reading that the first Counter (21) n cycles after setting in the first predeterminable counter reading emits a signal at one of its outputs (B, C) when the horizontal line of the Crosshair should be on the nth line that the clock input (Cl) of a second Counter (Z2) the pixel clock (DT) is fed that the second Counter (z2) with each pulse of the line clock (ZT) to a second predeterminable Counter reading is set that the second counter (Z2) in each case m clocks after setting in the second predeterminable counter reading at one of its outputs (B, C) a signal emits when the vertical line of the crosshair passes through the mth pixel of a every line should go that the signal that the first counter (Z1) at one of its Outputs (B, C), the light keying of the nth line causes and that the signal, that the second counter (Z2) outputs at one of its outputs (B, C), the light key of the m-th pixel on each line. 2. The method according to claim 1, characterized in that the first Counter (Z1), the counter reading of which is reduced by one with each pulse of the line clock (ZT) is set to the count n with each pulse of the picture clock (BT) that the second counter (z2), the counter reading of which with each pulse of the pixel clock (DT) is decreased by one, it is set to the counter reading m that the signal, that the first counter (Z1) outputs at its borrow output (B) when the count is zero, highlighting the nth line causes the signal that the second counter (Z2) emits at its borrow output (B) when the count is zero, the light keying of the m-th Pixel on each line causes and that the number n in a first and the number m can be stored and deleted in a second coordinate memory (K1, K2). 3. The method according to claim 1, characterized net, that the first counter (Z1), whose counter reading with each pulse of the line clock (ZT) is increased by one, with each pulse of the image clock (BT) on the counter reading which results from the complement to n increased by one that the second counter (Z2), the counter reading of which with each pulse of the pixel clock (DT) is increased by one, with each pulse of the line clock (ZT) on the counter reading which results from the complement to m increased by one, that the Overflow signal sent by the first counter (Z1) to its carry output at its maximum level (C) outputs, highlighting the nth line causes the overflow signal, the the second counter (Z2) emits at its highest level at its carry output (C), the highlighting of the m-th dot on each line and that the number n can be stored in a first coordinate memory and the number m in a second coordinate memory (K1, K2) and are erasable. 4. Circuit arrangement for performing the method according to claim 2, characterized in that the clock input (Cl) of the first counter (Z1) with the line clock output (ZT) and the clock input (Cl) of the second counter (Z2) with the pixel clock output (DT) of a screen control device (S) is connected, that the load input (L) of the first counter (Z1) with the image clock output (BT) and the load input (L) of the second counter (Z2) with the line clock output (ZT) of the Screen control device (S) is connected that the borrow output (B) of the first Counter (Z1) with the first input and the borrow output (B) of the second counter (z2) connected to the second input of a first OR gate (01) is that the output of the first OR gate (01) with the first input of a second Or gate (02) is connected, the second input of which is connected to the video signal output (VS) of the screen control unit (S) and its output with the video amplifier (W) of the display device is connected that the data inputs of the first counter (Z1) via a first data line (D1) to the first coordinate memory (K1) and the data inputs of the second counter (Z2) via a second data line (D2) the second coordinate memory (K2) are connected and that the first and the second Coordinate memory (K1, K2) via a third common data line (D3) with the Computer (R) of the display device is connected. 5. Circuit arrangement for performing the method according to claim 3, characterized in that the clock input (Cl) of the first counter (Z1) with the line clock output (ZT) and the clock input (Cl) of the second counter (Z2) with the pixel clock output (DT) of a screen control device (S) is connected, that the load input (L) of the first counter (Z1) with the image clock output (BT) and the Load-Ringana (L) of the second counter (Z2) with the line clock output (ZT) of the Screen control device (S) is connected to the carry output (C) of the first Counter (Z1) with the first input and the carry output (C) of the second counter (Z2) is connected to the second input of a first OR gate (01) that the Output of the first OR gate (01) with the first input of a second OR gate (02) is connected, the second input of which is connected to the video signal output (VS) of the screen control unit (S) and its output with the video amplifier (W) of the display device is connected that the data inputs of the first counter (Z1) via a first data line (D1) to the first coordinate memory (K1) and the data inputs of the second counter (Z2) via a second data line (D2) the second coordinate memory (K2) are connected and that the first and second Coordinate memory (K1, K2) via a third common data line (D3) with the Computer (R) of the display device are connected. 6. Circuit arrangement according to claim 4, characterized in that the load input (L) of a third counter (Z3) with the image clock output (BT) of the Screen control device (S) is connected that the clock input (Cl) of the third Counter (Z3) and the load input (L) of a fourth counter (Z4) with the line clock output (ZT) of the screen control device (S) are connected that the clock input (Cl) of the fourth counter (Z4) with the pixel clock output (DT) of the screen control device (S) is connected that the borrow output (B) of the third counter (Z3) with the third Input of the first OR gate (01) is connected that the borrow output (B) of the fourth counter (Z4) connected to the fourth input of the first OR gate (01) is that the data inputs of the third counter (Z3) via a fourth data line (D4) with a third coordinate memory (K3) are bound that the data inputs of the fourth counter (Z4) via a fifth data line (D5) are connected to a fourth coordinate memory (K4) and that the third and fourth coordinate memory (K3, K4) connected to the common third data line (D3) are. 7. Circuit arrangement according to claim 5, characterized in that the load input (L) of a third counter (Z3) with the image clock output (BT) of the Screen control device (S) is connected that the clock input (Cl) of the third Counter (Z3) and the load input (L) of a fourth counter (Z4) with the line clock output (ZT) of the screen control device (S) are connected that the clock input (Cl) of the fourth counter (Z4) with the pixel clock output (DT) of the screen control device (S) is connected that the carry output (C) of the third counter (Z3) with the third Input of the first OR gate (01) is connected that the carry output (C) of the fourth counter (Z4) connected to the fourth input of the first OR gate (01) is that the data inputs of the third counter (Z3) via a fourth data line (D4) are connected to a third coordinate memory (K3) that the data inputs of the fourth counter (Z4) via a fifth data line (D5) with a fourth coordinate memory (K4) are connected and that the third and fourth coordinate memory (K3, K4) are connected the common third data line (D3) are connected. 8. Circuit arrangement according to claim 6, characterized in that the borrow output (B) of the first counter (Z1) with the first input a first NAND gate (NA1) and to the first input of a first NOR gate (N01) is connected, the output of which is connected to the first input of the first OR gate (01) is connected that the borrow output (R) of the second counter (Z2) with the first input of a second NAND gate (NA2) and with the first input one second NOR gate (N04) is connected, the output of which is connected to the second input of the first OR gate (01) is connected that the borrow output (B) of the third Counter (Z3) with the second input of the first NAND gate (NA1) and with the first The input of a third NOR gate (N02) is connected, the output of which is connected to the third Input of the first OR gate (01) is connected that the Borrow output (13) of the fourth counter (Z4) with the second input of the second NAND gate (NA2) and is connected to the first input of a fourth NOR gate (N03) whose Output is connected to the fourth input of the first OR gate (01) that the output of the first NAND gate (NA1) with the clock input of a first flip-flop (FF1) is connected that the output of the second NAND gate (nu2) with the clock input a second flip-flop (FF2) is connected that the input of the first and the second flip-flops (FF1, FF2) is on "Low", while the J input of the first and the second flip-flop (FF1, FF2) is "high" that the PReset input of the first flip-flops (FF1) with the image clock output (BT) of the screen control device (S) is connected that the PReset input of the second flip-flop (FF2) with the line clock output (ZT) of the screen control device (S) is connected that the Q output of the first Flip-flops (FF1) connected to the first input of a first AND gate (U1) whose output is connected to the second input of the second and fourth NOR gate (N04, N03) is connected that the Q output of the second flip-flop (FF2) with the first input of a second AND gate (U2) is connected, the output of which is connected to connected to the second input of the first and third NOR gates (N01, N02) and that the interconnected second inputs of the first and second AND gates (U1, U2) are connected to the computer (R). 9. Circuit arrangement according to claim 7, characterized in that the carry output (C) of the first counter (Z1) with the first input of a first NAND gate (NA1) and connected to the first input of a first NOR gate (N01) whose output is connected to the first input of the first OR gate (01) is that the carry output (C) of the second counter (Z2) with the first input of a second NAND gate (nu2) and to the first input of a second NOR gate (N04) is connected, the output of which is connected to the second input of the first OR gate (01) is connected that the carry output (C) of the third counter (Z3) with the second Input of the first NAND gate (A1) and to the first input of a third NOR gate (N02) is connected, the output of which is connected to the third input of the first OR gate (01) is connected that the carry output (C) of the fourth counter (Z4) with the second A- output of the second NAND gate (NA2) and the first input a fourth NOR gate (N03) is connected, the output of which is connected to the fourth input of the first OR gate (01) is connected that the output of the first NAND gate (NA1) is connected to the clock input of a first flip-flop (FF1) that the output of the second NAND gate (NA2) with the clock input of a second flip-flip (FF2) connected that the K input of the first and second flip-flops (FF1, FF2) is on "Low" while the J input of the first and second flip-flops (FF1, FF2) is on "HighN" that the PReset input of the first flip-flop (FF1) with the image clock output (BT) of the screen control unit (S) is connected that-the PReset input of the second flip-flops (FF2) with the line clock output (ZT) of the screen control unit (S) is connected that the O-Ausoana of the first flip-flop (FF1) with the first Input of a first AND gate (U1) is connected, the output of which with the. second A qana of the second and fourth NOR gates (N04, N03) is connected to that of the Q output of the second flip-flop (FF2) with the first input of a second AND gate (U2) whose output is connected to the second input of the first and the third NO gate (01, N02) is connected and that the interconnected second inputs of the first and second AND gates (U1, U2) are connected to the computer (R). 10. The method according to claim 1, 2 or 3 or circuit arrangement according to claim 4, 5, 6, 7, 8 or 9, characterized in that the counter (Z1, Z2, Z3, Z4) dual counters are provided.